Casting Doubts On The Molecular Mechanism Of 'Read-Through' Drug PTC124/Ataluren

A drug developed to treat genetic diseases such as Duchenne muscular dystrophy and cystic fibrosis may need a radical rethink. In a new study published in the open access journal PLOS Biology, researchers question the mechanistic basis of the drug called PTC124 (also known as Ataluren), casting doubt as to whether it has the molecular effects that are claimed for it. This may have implications for its effectiveness in treating genetic diseases.

An estimated 10% of all human genetic diseases are caused by nonsense mutations. These cause ribosomes to stop dead in their tracks, leaving the proteins that they are making incomplete, often with devastating effects. For example, a subset of cases of cystic fibrosis are caused by nonsense mutations in the gene encoding CFTR, a transmembrane chloride ion channel. The vision behind PTC124, one of a class of so-called "read-through" drugs, was to trick the ribosome into ignoring these premature stop signs, so that enough full-length protein could be made to substantially improve the lot of patients. PTC124 was initially shown to be effective in promoting read-through of mutations that cause Duchenne muscular dystrophy, a severe, lethal and relatively common genetic disease. Subsequently, however, despite some positive results, reports of PTC124's efficacy for this and other genetic diseases have been mixed, and people in the field have started to question the efficacy of the drug.

In the new study, Stuart McElroy, Irwin McLean and colleagues at the University of Dundee question the validity of the elegant screening experiment initially used to identify PTC124. This was based on a system whereby an effective read-through drug would cause the ribosomes to make a "reporter" enzyme named luciferase; this enzyme was originally isolated from fireflies, and can be detected by its ability to produce light. McElroy and colleagues confirmed previous studies that suggested PTC124 instead deceives the drug screening system via a direct effect on the luciferase enzyme, rather than by causing read-through. They then showed that this doesn't occur when they used alternative reporter enzymes. But does PTC124 nevertheless cause translational read-through? The answer, apparently, is no; the authors went on to systematically test the effects of PTC124 on the read-through of all possible nonsense mutation contexts and on a range of scenarios. In each case, PTC124 failed to show any effect. The originally reported effects are therefore likely to have occurred by some mechanism other than read-through.

It should be noted that McElroy and colleagues only tested cells (not intact animals), that they only look at read-through activity, and that there are several publications suggesting clinical efficacy of PTC124 (particularly for cystic fibrosis) that are not challenged by this study. It is well known that some drugs may act by means other than originally intended but nevertheless remain effective. However, the study does raise questions about the drug's mechanism and efficacy for genetic diseases, indicating that in instances where PTC124 does have beneficial effects, this may be down to serendipity rather than the purported mechanism of translational read-through.

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Casting Doubts On The Molecular Mechanism Of 'Read-Through' Drug PTC124/Ataluren

Funding: This study was supported by the Medical Research Council (Grant number G0700314, to WHIM, University of Dundee Devolved MRC DPFS Portfolio G0900864/D043). Research in the McLean laboratory is also supported by grants from the Medical Research Council (grants G0801742 and G0802780); The Wellcome Trust (grants 090066/B/09/Z and 092530/Z/10/Z); and DEBRA UK. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing Interests: I have read the journal's policy and have the following conflicts. We discovered the lack of efficacy of PTC124 by conducting our own drug discovery programme to discover and develop nonsense mutation read-through agents. Subsequent to the completion of this work, WHIM initiated a partnership with Glaxo SmithKline (GSK) on a closely related project. The work described herein was conducted prior to, and independently of, any interaction with GSK. No materials or support were received from GSK and no agreements are in place with GSK concerning the execution or publication of this work, although they were at one point involved in discussions about its publication. The collaboration with GSK has now ended.

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